Method and device for actively reducing clutch grabbings in a motor vehicle

ABSTRACT

A method and a device with which disturbing vibrations are diminished at least in the height of their amplitude. A control and regulating device ( 24 ) and suitable sensors ( 34, 36, 41 ) activate a device ( 7, 11, 15, 23, 29, 30 ) when previously established limiting values are exceeded with regard to procedure, with which components of the motor vehicle are influenced such that the disturbing vibrations are damped or compensated.

In motor vehicles, vibrations can occur during the slippage phase of a clutch in the power train, which are generated in the motor vehicle clutch. As can be gathered from the technical article, “Testing Power Trains as Exemplified by Clutch Grabbing: Whole Power Train Development,” ATZ Automobile Engineering Journal 103 (2001) 44 ff., these vibrations arise when periodic torques are generated in connection with a slipping clutch, which torques lie in the characteristic frequency of the power train dynamically separated by the clutch.

These vibrations, also known as clutch grabbing, can be self-excited or automatically excited. Self-excited clutch grabbing is caused by a drop of the clutch facing friction value in relation to the rate of sliding and can be rather considerable as a function of the power train overall damping.

Automatically excited clutch grabbing is in contrast stimulated by external sources in relation to the friction partners, including crankshaft axial vibrations or parallel deviations on the clutch pressure plate, in combination with an angular offset between the clutch pressure plate and the clutch disk that supports the friction lining.

The torsional vibrations that arise in the power train in connection with clutch grabbing are converted by the driven motor vehicle wheels into longitudinal oscillations of the entire motor vehicle and are transmitted via the service elements and via the motor vehicle seats to the motor vehicle occupants. Thus clutch grabbing is perceived by the vehicle passengers as unpleasant vibrations or oscillations that can also be associated with noise stress.

Although a high-level damping in the components of the power train does reduce the oscillation amplitudes with automatically excited clutch grabbing, this is nonetheless often an unrealistic demand due to the general wish for the lowest possible fuel consumption for a motor vehicle, since a permanently high damping in the power train is basically attainable only through a constantly active elevation of friction losses, for example in the transmission, in the bearings and in the seals.

Inserting a clutch friction lining with an increasing friction value curve over the rate of sliding has been proposed, for example, as a countermeasure for reducing clutch grabbing and the disturbing longitudinal oscillations of the motor vehicle that go along with it. The friction linings available at this time, however, are not capable of this.

Another possibility for reducing clutch grabbing consists in further reducing the manufacturing tolerances in the clutch region, however this would be possible only with a very high manufacturing expenditure, and it will produce a rather modest contribution to reducing clutch grabbing (“Grabbing-Causes and Remedies,” Prof. Albert Albers, Dr. Eng., Daniel Herbst, Cert. Eng. in: 6^(th) LuK Colloquium, 1998).

Metrological recording of a clutch jerking in connection with a starting clutch or a converter bridging clutch by means of suitable sensors and a control and regulating device as well as active measures for ending this clutch jerking are moreover known from EP 845 616 A2. These measures consist of altering the ignition time of an internal combustion engine connected with the clutch via drive engineering in order thus to act upon the input torque into the clutch. Another measure provides for increasing the contact pressure of the clutch pressure plate on the clutch friction lining, whereby a slippage operation of the clutch offering some advantages is no longer possible.

Since the known measures bring on unsatisfactory results with respect to avoiding or reducing clutch grabbing, the object of the invention consists in presenting a method and device with which the disturbing rotational vibrations of the power train or the disturbing longitudinal oscillations can at least be diminished in their amplitude height.

The accomplishment of this objective is disclosed in the characterizing features of the method and device main claims, while advantageous further developments and refinements of the invention can be inferred from the dependent claims.

With respect to the method of the invention, it is accordingly provided that the disturbing vibrations are recognized and evaluated by a control and regulating device using suitable sensors. If previously established limiting values are exceeded, then the control and regulating device acts upon at least one motor vehicle device such that by its activation, the disturbing vibration in the power train and/or in the entire motor vehicle is completely eliminated or at least damped in its amplitude. For this purpose, a rotating component of the motor vehicle power train is acted upon by the control and regulating device via the at least one motor vehicle device such that the rotating component or components are continuously or periodically braked in their rotational motion or are stimulated to a compensatory vibration.

In this connection, it is provided that the at least one device acts on at least one motor vehicle component such that a longitudinal oscillation of the overall motor vehicle stimulated by the vibrations in the power train is eliminated or at least damped in its amplitude height. To generate a compensatory vibration that will damp the disturbing vibrations in the power train or in the entire motor vehicle, at least in their amplitude, or for a damping braking intervention on rotating components in the power train, this compensatory vibration or the brake intervention has the same or a similar frequency and a vibration phase offset in relation to the vibration that is acting in a disturbing manner. This vibration phase offset leads to a mutual compensation of the vibration amplitudes.

In a refinement of the method of the invention, it can be provided that a starting or gear box of the motor vehicle transmission is actuated by the control and regulation device such that its torque transmission capacity oscillates with the frequency of the disturbing vibration and has the mentioned vibration phase offset in relation to this, due to which the amplitude of the disturbing vibration is reduced to a predetermined value.

In another variant of the control method, it is provided that a service brake acting on the input shaft of a transmission is actuated by the control and regulating device such that, with a rise in the vibration amplitude of the disturbing vibration, the service brake brakes the transmission input shaft to a rotational speed that reduces the amplitude of the disturbing vibration to a predetermined value that does not have a disturbing action. Such a control method is especially appropriate for use in power trains in which the transmission is constructed as an automatic or automatically shiftable claw shift transmission.

In motor vehicles in whose power train an abrasion-free permanent brake (for example, an electromagnetic retarder arranged behind the transmission in terms of drive engineering) is inserted, this permanent brake can be actuated via the control and regulation device such that, with a rise in the vibration amplitude of the disturbing vibration, the permanent brake brakes the rotational speed of the wheel drive shafts of the motor vehicle to the extent that the amplitude of the disturbing vibration is reduced to a predetermined value.

Another variant of the method of the invention provides that the service brakes of the driven motor vehicle wheels are actuated by the control and regulating device such that here too, with a rise in the vibration amplitude of the disturbing vibration, the motor vehicle wheels are slowed down to a rotational speed through which the rotary or longitudinal oscillation disturbing the amplitude is reduced to a predetermined value.

It is also possible to act upon an output actuator of the motor vehicle internal combustion engine via the control and regulating device. For this, the rotational speed of the internal combustion engine is altered in accordance with the method in the event of a perceived rise in the vibration amplitude of the disturbing vibration such that this is oscillated with the frequency of the harmful vibration, however its phase displacement to this is such that the amplitude of the disturbing vibration is reduced to a predetermined and not disturbing value.

Such an operating behavior of the internal combustion engine is especially appropriate if the clutch grabbing described at the beginning occurs while switching the motor vehicle. The control and regulating device here regulates the rotational speed of the internal combustion engine when clutch grabbing occurs, so that during one of these known switching travels, the switching rotational speed (for example, the idling rotational speed) of the internal combustion engine is increased such that the amplitude of the disturbing vibration is reduced to a predetermined value. The switching rotational speed can for this purpose be increased at once or in stages until the vibration compensation is attained.

If there is a double clutch transmission present in the power train of the motor vehicle, the two clutches can be used to influence the disturbing vibrations such that, upon recognizing the clutch grabbing, the second clutch is activated in a controlled manner by the control and regulating device with respect to its torque transfer capacity in addition to the first clutch (which is closed for the gear step set) as frequently and as long, until the amplitude of the disturbing vibration is reduced to a predetermined value. In this way, the periodic opening and closing of the second clutch of the double clutch transmission will preferably take place with the same frequency that the disturbing frequency has, but will nonetheless have a vibration phase offset in relation to this through which the vibration amplitudes will at least be largely compensated.

In another refinement of the control method of the invention, it can be provided that, in a power train with a gear box, its synchronization device is activated in a braking manner in the region of a not just shifted transmission step as frequently and as long as it takes until the amplitude of the disturbing vibration is reduced to a predetermined value.

Finally, it should be mentioned that the control and regulating device can record the rotational speeds of the clutch input side and the clutch output side in implementing its control and regulation objectives described above with the aid of rotational speed sensors, and the longitudinal acceleration of the motor vehicle is ascertainable with the aid of a longitudinal acceleration sensor which can, for example, be arranged in the region of a motor vehicle seat.

With respect to the device for implementing the control and regulation functions described, first of all a control and regulating device is arranged in the motor vehicle, which is preferably designed as a microcomputer. The microcomputer can moreover be a transmission or motor control device, for example. This control and regulation device is connected with the sensors for recording disturbing vibrations in the vehicle via sensor lines. The control lines in contrast lead to devices in the power train with which motor vehicle parts can be set into vibration or braked such that their frequency, vibration amplitude and phase angle in relation to the frequency, vibration amplitude and phase angle of the disturbing vibration leads to a damping of the amplitude of the disturbing vibration when these two vibrations are superimposed.

Rotational speed sensors that, for example, record the rotational speed of the input side or the output side of a clutch, preferably a starting clutch or gearbox or other rotating parts in the power train, belong to the sensors mentioned. Moreover the control and regulating device is preferably connected to a vibration sensor that can sense a disturbing vibration in the power train or in the motor vehicle overall. Preferably longitudinal oscillations of the entire motor vehicle in the region of the motor vehicle seat can be recorded with such a sensor as mentioned in the description of the method.

In a further refinement of the device of the invention, it is provided that the control and regulating device is connected to a control device for activation of the clutch via a control line. Through this construction, the clutch can be stimulated to the desired compensatory vibration behavior preferably independently of a conventional clutch activation device. Or, for example, a clutch pressure plate can be periodically or continuously subjected to contact pressure with a higher contact pressing force on the friction lining of the clutch disk.

Moreover, it can be provided with respect to the device of the invention that the control and regulating device is connected to an actuator for activation of a synchronization device in an automated or automatic gearbox via a control line. Such an actuating device can be a hydraulically or pneumatically activatable piston-cylinder arrangement with which a clutch sleeve arranged in the transmission on a transmission shaft is axially displaceable. This clutch sleeve acts in an inherently known manner on axially displaceable synchronizing rings with the help of which a loose wheel can be engaged on the transmission shaft in the torque transmission path such that it can be braked.

In implementing the method of the invention, it can also be provided that the control and regulating device is connected to the actuating device of a service brake for braking an input shaft of a gearbox, preferably an automated claw clutch transmission, via a corresponding control line. In accordance with the method, this service brake is then periodically or continuously activatable independently of its synchronization objectives in connection with a gear shifting for slowing down the transmission input shaft and therewith for reducing the disturbing vibrations.

In another refinement of the device for implementing the control and regulation method of the invention, it is provided that the control and regulation device is connected to a retarder device, thus with an abrasion free permanent brake for braking the drive shaft of the motor vehicle drive wheels via a control line. In the end, the control and regulation method of the invention can also be conducted with a device in which the control and regulation device is connected to actuators on the service brakes of the driven motor vehicle wheels via control lines. Through a corresponding brake intervention by the retarder or by the service brake on the driven motor vehicle wheels, although the occurrence of unfavorable rotary vibrations on the clutch cannot be avoided, with such a measure the damping of the drive train can be periodically increased or constantly increased for the period the clutch grabbing occurs so that the amplitudes of the disturbing vibrations are not unpleasantly high.

Finally, it can be provided that the control and regulating device is connected to a rotational speed adjustment device, thus for example with the output actuator of the internal combustion engine, via a control line. The desired result can also be attained through the procedural influencing of the motor rotational speed.

The control and regulation method of the invention as well as the device for implementing this method can best be explained with the aid of an exemplary embodiment of the invention. A drawing is appended to the description for this in whose sole FIGURE the drive train of a motor vehicle as well as a large number of variants of the device of the invention are represented in schematic representation.

In this drive train an internal combustion engine 1 can be connected as is inherently known with a gear box 8 via drive engineering through a starting clutch 4. For this the clutch 4 has an input side 5, which is connected to the crankshaft 2 of the internal combustion engine 1, as well as an output side that stands in connection with the input shaft 3 of the transmission 8. The output shaft 16 of this transmission 8 drives a differential transmission 17 via an abrasion-free permanent brake 23, thus for example an electromagnetically operating retarder, from which two drive shafts 18 for motor vehicle wheels 19, 20 proceed.

Service brakes 21, 22 are arranged on the motor vehicle wheels 19, 20, which can be constructed as drum or disk brakes. Moreover a control and regulation device 24 is represented, which preferably includes a microcomputer and can be an integral component of a motor or transmission control apparatus.

Finally, this FIGURE illustrates a motor vehicle seat 37 as a final motor vehicle main component on which a motor vehicle occupant can perceive vibrations in the motor vehicle. The motor vehicle seat 37 is physically fastened on the motor vehicle floor via a spring damping system, which is here indicated by a spring 38 and a damping piston 39, for transmission of the vibrations generated by the drive train in this simplified representation.

As was explained at the beginning, rotary vibrations arising in the motor vehicle clutch 4 in certain operating phases, as for example during the switching operation of the motor vehicle, extend over all main components of the drive train to the motor vehicle wheels 19, 20 where these rotary vibrations are converted to longitudinal oscillations and are introduced into the motor vehicle body via the wheel suspension. These longitudinal oscillations are perceived as unpleasant by the driver situated on the motor vehicle seat 37 so that the measures of the invention are required to reduce these vibrations at least to a tolerable level.

For this it is first of all necessary to establish the rotary vibrations in the drive train or the longitudinal oscillations of the body resulting from them via corresponding sensors and to communicate them to the control and regulation device. For this purpose, two alternate types of sensors are represented in this drawing, which can be used individually or jointly. Thus one rotational speed sensor 34, 36 is respectively arranged on the input side 5 and on an output side 6 of the clutch 4, with which the clutch rotary vibrations of the clutch 4 that characterize grabbing can be established. This rotational speed information can be forwarded via sensor lines 33, 35 to the control and regulation device 24. The rotational speed values that characterize the disturbing rotary vibrations can, however, also be metrologically ascertained on all other rotating parts of the drive train.

Another possibility for sensing the disturbing vibrations in the motor vehicle consists, for example, in arranging a vibration sensor 41 in the region of the motor vehicle seat 37 for recording motor vehicle longitudinal oscillations, which sensor is connected to the control and regulating device 24 mentioned through a separate sensor line 32.

Once the control and regulation device 24 has determined, on the basis of the sensor information mentioned, that the rotary vibrations ascertained on the clutch 4, for example, and/or the longitudinal oscillations occurring on the motor vehicle body exceed a predetermined amplitude limiting value stored in the control and regulation device, countermeasures are taken which basically all serve to reduce the amplitude of the disturbing vibration (motor vehicle longitudinal oscillation or rotary vibration in the drive train) to the extent that these are preferably reduced below the perception threshold of a motor vehicle occupant situated on the motor vehicle seat. This is attained in that at least one device on or in the drive train of the motor vehicle acts on at least one component in the motor vehicle drive train such that the latter is continuously or periodically braked in its rotary motion or is stimulated to a vibration so that the vibration amplitude of the disturbing vibration is reduced.

A first variant for conducting this control and regulating method can be technically realized in that there is active influence upon a rotating component of the clutch 4 using an actuating device 7, here a piston-cylinder arrangement, such that the disturbing rotary motion of the clutch 4 is damped. The actuating device 7 is connected with the output side 6 of the clutch 4 in this exemplary embodiment of the invention. The direction of action of the piston-cylinder arrangement 7 is moreover preferably oriented in or against the direction of rotation of the clutch component 6, even though an axial action upon the clutch 4 can also be appropriate. The piston-cylinder arrangement 7 receives the activation signal through a driving power 31 of the control and regulation arrangement 24.

In another refinement of the invention, a service brake 11 can be used to reduce the disturbing vibrations present in the drive train. Such a service brake 11 is, as a rule, provided anyway in automated claw gear transmissions 8 in order with its aid to brake down the rotational speed of the transmission input shaft 3 to the synchronizing rotational speed of the higher gear in up-shifting processes. This service brake 11 can, however, also be independently activated or deactivated of such shifting synchronization objectives by the control and regulation device 24 for this to reduce the disturbing rotary vibrations of the clutch grabbing to an extent that is tolerable to the rider. Thus this service brake 11 can, for example, be closed momentarily if the control and regulating device 24 determines a rising flank of the drive train rotary motion or the motor vehicle longitudinal motion mentioned. The amplitude of the disturbing vibrations is reduced in this way.

The braking effect described can also be obtained in connection with completely synchronized transmissions in that step synchronization means of an unshifted gear are, likewise, activated when the control and regulating device 24 determines a rising slope of the drive train rotary vibration or the motor vehicle longitudinal oscillation. In this way, the amplitude of the disturbing vibrations is damped. A synchronization device 10 is provided in the transmission 8 in the schematic drawing explained here in which a clutch sleeve 13 arranged torsionally resistant, but axially displaceable on the transmission output shaft 16, interacts with a synchronizing ring 14 whose inclined synchronizing surface is pressed during an axial displacement on the transmission output shaft 16 against a synchronizing incline 12 of a toothed wheel 9 arranged on this shaft 16. The clutch sleeve 13 is axially moved by an actuating device 15 (piston-cylinder arrangement) on the transmission output shaft 16, wherein the actuating device 15 receives its actuating commands via a control line 27 from the control and regulating device 24. Here the toothed wheel 9 is at least temporarily connected torsion resistant with the transmission output shaft 16 which exerts a braking and rotary vibration damping action on the drive train downstream.

Furthermore the FIGURE shows that the abrasion-free service brake (retarder) 23, which is arranged in accordance with drive engineering behind the transmission 8, can also be used for damping rotary vibrations by braking a drive train shaft, for example a cardan shaft. With the rapidly reacting retarder 23, the latter can also be used for generating a compensatory vibration in which the phase angle of the compensatory vibration is displaced in relation to the phase angle of the disturbing rotary vibration in the drive train such that the overlapping vibrations at least partially cancel each other out.

The effect described can also be attained by a corresponding activation of the service brakes 21, 22 of the driven motor vehicle wheels 19, 20 which, likewise, takes place according to the aforementioned control rules. It is particularly advantageous with this technical solution that no additional actuators on the service brakes 21, 22 are needed, but available electro-hydraulic brake actuating devices can be actuated via control lines 29, 30 by the control and regulation device 24.

Moreover, the internal combustion engine 1 can also be controlled and regulated with regard to its motor rotational speed by the control and regulating device 24 via a control line 25, such that a motor rotational speed vibration with identical frequency is built up when the control and regulating device 24 determines a rising curve of the aforementioned drive train rotary vibration and the motor vehicle longitudinal oscillation. The grabbing vibration is then damped by the then different rotational speed differences on the clutch.

The disadvantage with this method is that a sawtooth pattern is contained over the course of time of the motor rotational speed, however it is felt to be significantly less disadvantageous by a motor vehicle occupant than the grabbing vibrations described.

It can also be provided that the control and regulation device 24 disposes of suitable resources for determining a switching operation of the motor vehicle. In such an operating case, the switching rotational speed of the internal combustion engine is raised by the control and regulation device 24 when the clutch grabbing occurs. This can take place step by step by corresponding signals through the control line 25, for example, to the power actuator of the internal combustion engine 1. This internal combustion motor-related damping of the grabbing vibration is also advantageous because no additional actuator equipment is necessary for this.

Finally, in the interest of completeness, it should be pointed out that even with a power train with a double clutch transmission (not represented in the FIGURE), a damping of the clutch grabbing vibrations can be attained in that, using the clutch actuator of the second transmission clutch, the latter can be momentarily, periodically closed at least partially with the already mentioned phase offset in order to reduce the amplitude of the disturbing vibration by the braking action so triggered.

The method of the invention and the device of the invention for conducting the aforementioned method can include individual or even several of the different method and device refinements.

In addition to the sensors represented, other rotational speed sensors can be used in the drive train whose signals yield the necessary information through a corresponding conversion in an electronic unit. Reference numerals 1 internal combustion engine 2 crankshaft 3 transmission input shaft 4 clutch 5 input side of the clutch 6 output side of the clutch 7 actuating device, piston-cylinder arrangement 8 transmission 9 toothed wheel 10 synchronization device 11 service brake 12 synchronization incline 13 clutch sleeve 14 synchronizing ring 15 actuating device, piston-cylinder arrangement 16 transmission output shaft 17 differential transmission 18 drive shafts of the driven motor vehicle wheels 19 motor vehicle wheel 20 motor vehicle wheel 21 service brake 22 service brake 23 retarder, permanent brake 24 control and regulating device 25 control line 26 control line 27 control line 28 control line 29 control line 30 control line 31 control line 32 sensor line 33 sensor line 34 rotational speed sensor 35 sensor line 36 rotational speed sensor 37 motor vehicle seat 38 spring 39 damping piston 40 motor vehicle floor 41 vibration sensor 

1-21. (canceled)
 22. A method for reducing disturbing vibrations in a motor vehicle in which the disturbing vibrations are determined by a control and regulating device using suitable sensors, at least one device is activated when previously established limiting values are exceeded by the control and regulating device such that an amplitude of the disturbing motion is completely eliminated or at least damped, the at least one device acts in at least one rotating component in a motor vehicle drive train such that a latter component or components are continuously or periodically braked in rotary motion when the disturbing vibrations occur or are excited to a compensatory vibration.
 23. The method according to claim 22, further comprising the steps of the compensatory vibration or brake intervention has a same or a similar frequency as the disturbing vibration, but has a phase offset in relation to the disturbing vibration that leads to a reduction in amplitude of the disturbing vibration.
 24. The method according to claim 22, further comprising the steps of one of a starting or gear box in the drive train is actuated by the control and regulating device such that torque transmission capacity oscillates with the frequency of the disturbing vibration and has a phase offset in relation to the disturbing vibration through which the amplitude of the disturbing vibration is reduced to a predetermined value.
 25. The method according to claim 22, further comprising the steps of a service brake acting on an input shaft of the drive train is actuated by the control and regulating device such that with a rise in the vibration amplitude of the disturbing vibration, the service brake brakes the transmission input shaft to a rotational speed that reduces the amplitude of the disturbing vibration to a predetermined value.
 26. The method according to claim 22, further comprising the steps of an abrasion-free permanent brake arranged according to drive engineering behind a transmission is actuated by the control and regulating device such that with a rise in the vibration amplitude of the disturbing vibration, the permanent brake brakes a rotational speed of wheel drive shafts such that the amplitude of the disturbing longitudinal oscillation is reduced to a predetermined value.
 27. The method according to claim 22, further comprising the steps of service brakes are actuated on driven motor vehicle wheels by the control and regulating device such that with a rise in the vibration amplitude of the disturbing vibration, the driven motor vehicle wheels are braked to a rotational speed via which the amplitude of the disturbing vibration is reduced to a predetermined value.
 28. The method according to claim 22, further comprising the steps of a motor vehicle internal combustion engine is actuated by the control and regulating device such that a rotational speed of the internal combustion engine oscillates with a frequency of the disturbing vibration, but has a phase offset in relation to the frequency of the disturbing vibrations through which the amplitude of the disturbing vibration is reduced to a predetermined value.
 29. The method according to claim 28, further comprising the steps of the control and regulating device increases a switching rotational speed during a switching travel recognized by this, preferably an idling rotational speed of the internal combustion engine, such that the amplitude of the disturbing vibration is reduced to the predetermined value.
 30. The method according to claim 29, further comprising the steps of the switching rotational speed of the internal combustion engine is increased step by step until the amplitude of the disturbing vibration is reduced to the predetermined value.
 31. The method according to claim 22, further comprising the steps of with a double clutch transmission, a second clutch is activated with respect to torque transmission capacity in addition to a first clutch, which is closed for a shifted step, so far and as frequently and with such a vibration phase offset in relation to the disturbing vibration until an amplitude of the disturbing vibration is reduced to a predetermined value.
 32. The method according to claim 22, further comprising the steps of a synchronization device for a not shifted transmission step is activated in connection with a gear box so far, as frequently and with such a vibration phase offset until the amplitude of the disturbing vibration is reduced to a predetermined value.
 33. The method according to claim 22, further comprising the steps of the control and regulating device records rotational speeds of a clutch input side and a clutch output side with aid of rotational speed sensors, and motor vehicle acceleration can be ascertained by the control and regulating device with aid of a sensor unit that recognizes longitudinal acceleration.
 34. A device for reducing disturbing vibrations in a drive train and in a motor vehicle in which the disturbing vibrations are determined by a control and regulating device which is connected with one or more of rotational speed sensors (34, 36) and vibration sensors (41) via sensor leads (32, 33, 35), for a purpose of recording the disturbing vibration, the control and regulating device is connected through signal engineering via control leads (25, 26, 27, 28, 29, 30, 31) with devices (7, 11, 15, 21, 22, 23), the control and regulating device being activated when previously established limiting values are exceeded by the control and regulating device such that the disturbing motion is completely eliminated or at least damped in amplitude, the device acts in at least one rotating component in the drive train such that latter component or components are continuously or periodically brought into vibration or braked in rotary motion when the disturbing vibrations occur or are excited to a compensatory vibration causing one or more of a vibration frequency, vibration amplitude and vibration phase angle to be constructed in relation to the one or more of a frequency, amplitude and vibration phase angle of the disturbing vibration causing a damping of the amplitude of the disturbing vibration with a superposition with the disturbing vibration.
 35. The device according to claim 34, wherein the rotational speed of one of the input side (5) or the output side (6) of a clutch (4), preferably one of a starting or gearbox, can be recorded with the rotational speed sensors (34, 36).
 36. The device according to claim 34, wherein a disturbing motor vehicle longitudinal oscillation, preferably in a region of a motor vehicle seat (37), can be recorded with the vibration sensor (41).
 37. The device according to claim 34, wherein the control and regulating device (24) is connected to an actuating device (7) for activating a clutch (4) via a control line (31).
 38. The device according to claim 34, wherein the control and regulating device (24) is connected to an actuating device (15) for activating a synchronization device (10) in a gear box (8) through a control line (27).
 39. The device according to claim 34, wherein the control and regulating device (24) is connected to a service brake (11) for braking a transmission input shaft (3) of a gear box (8) through a control line (26).
 40. The device according to claim 34, wherein the control and regulating device (24) is connected to an abrasion-resistant permanent brake (23) for braking motor vehicle drive shafts (18) through a control line (28).
 41. The device according to claim 34, wherein the control and regulating device (24) is connected to service brakes (21, 22) on driven motor vehicle wheels (19, 20) via control lines (28, 29).
 42. The device according to claim 34, wherein the control and regulating device (24) is connected to a rotational speed actuating device, preferably to a power actuator on an internal combustion engine (1) of the motor vehicle via a control line (25). 